Penicillium chrysogenum is an economically important ascomycete used as industrial producer of penicillin. However, with the exception of penicillin biosynthesis genes, little attention has been paid to the genetics of other aspects of the metabolism of this fungus. In this article we describe the first attempt of systematic analysis of expressed genes in P. chrysogenum, using a suppression subtractive hybridization approach to clone and identify sequences of genes differentially expressed in media with glucose or lactose as carbon source (penicillin-repressing or non-repressing conditions). A total of 167 clones were analysed, 95 from the glucose condition and 72 from the lactose condition. Genes differentially expressed in the glucose condition encode mainly proteins involved in the mitochondrial electron transport chain and primary metabolism. Genes expressed differentially in lactose-containing medium include genes for secondary metabolism (pcbC, isopenicillin N synthase), different hydrolases and a gene encoding a putative hexose transporter or sensor. The results provided information on how the metabolism of this fungus adapts to different carbon sources. The expression patterns of some of the genes support the hypothesis that glucose induces higher rates of respiration in P. chrysogenum while repressing secondary metabolism.

The cloning and characterization of the Thcut1 gene, which encodes a cutinase protein of the biocontrol fungus Trichoderma harzianum T34, is reported. Cutinases, which are secreted enzymes that hydrolyse cutin, belong to a class of serine esterases able to hydrolyze fatty acid esters and emulsified triglycerides. The Thcut1 gene was isolated by screening of a genomic DNA library from EST 2104, generated from a T. harzianum T34 cDNA library constructed under mycoparasitic and nutrient stress conditions, as a probe. Thcut1 shows similarity with fungal cutinase genes and is present as a single copy in the genome of T. harzianum. RNA blot analyses revealed that Thcut1 mRNA is strongly induced in vitro by olive oil and the cutin monomer 16-hydroxy-hexadecanoic acid and that it is repressed by glucose. Significant transcript levels were also detected when strawberry plants or pectin were present in the media and in the absence of glucose. Expression of the Thcut1 gene in Pichia pastoris gave rise to transformants with high esterase activity and a high level of secretion of the THCUT1 protein. Recombinant cutinase secretion at flask level indicated that P. pastoris transformants could be applied to set up the production of this enzyme at industrial scale.

Plasmid vectors containing theAMA1 sequence transformed with high efficiency and replicated autonomously inPenicillium chrysogenum. The efficiency of transformation ofP. chrysogenum was related to the length of theAMA1 fragment used for constructing the different autonomously replicating plasmids. One of the two palindromic inverted repeats ofAMA1 (the 2.2-kbSalI-HindIII fragment) is sufficient to confer autonomous replication and a high transformation efficiency. Deletion of the 0.6-kb central fragment located between the inverted repeats did not affect either the ability of the plasmids to replicate autonomously or the efficiency of transformation, but did alter the mitotic stability and the plasmid copy number. Deletion of any fragment of the 2.2-kb repeat caused the loss of the ability to replicate autonomously and reduced the transformation efficiency. Most of the transformants retained the original plasmid configuration, as multimers and without reorganization, after several rounds of autonomous replication. TheAMA1 region works as an origin of replication inP. chrysogenum andA. nidulans but not apparently inAcremonium chrysogenum.

An EST showing high values of identity with genes coding for small heat shock proteins (sHSPs) was selected from an EST library collection of Trichoderma virens T59. The cDNA gene (hsp23) with a sequence size of 645 bp long was amplified by PCR. The expression of this gene was evaluated in cultures grown at temperatures ranging from 4 to 41°C. An increased level of expression was detected when the fungus was grown at extreme temperatures (4, 10 or 41°C). A high-expression level was also observed when the fungus was grown in 10% ethanol for 4 h. The hsp23 gene was present as a unique copy in the T. virens genome, and a homologous gene was also present in other five investigated Trichoderma species. Strain T. harzianum T34 was transformed with the hsp23 gene from T. virens T59 under the control of the pki (pyruvate kinase) promoter from T. reesei and the ble (phleomycin resistance) gene as selection marker. Statistically significant differences were detected between the strains T34 and two selected transformants in the biomass quantities obtained after heat shock treatment and in the colony diameters after incubation at 4°C for 2 months.

The evolutionarily conserved Dim1 proteins belong to the TRX fold superfamily. An EST showing high identity values with genes coding for Dim1 proteins was selected from an EST library collection of Trichoderma virens T59. Here, we report the cloning, characterization, and functional analysis of a T. virens T59 TvDim1 gene. The TvDim1 gene, with a sequence size of 614 bp, was PCR-amplified and found to contain three introns. The TvDim1 gene was present as a single copy in the T. virens genome and was also present in another five Trichoderma strains investigated. Increased levels of expression and redox-activity were detected when the fungus was grown in the presence of H2O2. The overexpression and silencing of TvDim1 in T. harzianum T34 gave rise to transformants, with higher and lower growth, redox-activity, and quantities of biomass, respectively, than the wild-type strain after culture under oxidative stress.

A DNA fragment containing an open reading frame of 2016 nucleotides has been cloned from the DNA of Aspergillus awamori by hybridization with a probe internal to the KAR2 (BiP) gene of Saccharomyces cerevisiae. The 73.4-kDa-encoded protein showed very high similarity to the endoplasmic reticulum (ER) lumenal BiP protein of S. cerevisiae, Kluyveromyces lactis, Schizosaccharomyces pombe, and animal and plant cells. The BiP protein contains a polar N-terminal end followed by a 18-amino-acid strongly hydrophobic region corresponding to the leader peptide for transport through the ER membrane. In the C-terminal region the protein ends with the HDEL canonical ER retention signal that targets proteins to the lumen of the ER. The A. awamori bip gene contains three introns as shown by cloning and sequencing the putative intron regions from a cDNA library. The bip gene is transcribed as a monocistronic mRNA of 2.4 kb. Two transcription start sites located 160 and 233 bp upstream of the first translated ATG were identified by primer extension. The promoter region showed no consensus TATA box but it contains CCAAT and CreA boxes known to be involved in both stress and carbon-catabolite regulation of fungal promoters.

The high-level pigment-producing Monascus strain IBCC1 was characterized by random amplification of polymorphic DNA as M. purpureus. This technique allowed us to distinguish between M. purpureus and M. ruber strains. Transformation of Monascus species has not been previously reported. Protoplast formation and regeneration from M. purpureus IBCC1 was optimized by modification of growth media, lytic enzyme mixture, osmotic stabilizer and regeneration media. Of the Monascus transformants, 60% were found to be mitotically stable and retained the plasmid inserted in the chromosome after repeated sporulation cycles. Additionally, an Agrobacterium-mediated DNA transfer system was developed. The transformants obtained by Agrobacterium-mediated DNA transfer remained fully stable (98%) after four sporulation rounds and showed bands of hybridization corresponding to integration of the plasmid in different sites of the genome. The green fluorescent protein marker was well expressed in the M. purpureus transformants. The development of transformation systems is a basic tool for advanced genetic manipulation of the natural pigment producers, M. purpureus and M. ruber.

A 28.7-kb DNA region containing the gdhA gene of Aspergillus awamori was cloned from a genomic DNA library. A fragment of 2570 nucleotides was sequenced that contained ORF1, of 1380 bp, encoding a protein of 460 amino acids (Mr 49.4 kDa). The encoded protein showed high similarity to the NADP-dependent glutamate dehydrogenases of different organisms. The cloned gene was functional since it complemented two different Aspergillus nidulans gdhA mutants, restoring high levels of NADP-dependent glutamate dehydrogenase to the transformants. The A. awamori gdhA gene was located by pulsed-field gel electrophoresis in a 5.5-Mb band (corresponding to a doublet of chromosomes II and III), and was transcribed as a monocistronic transcript of 1.7 kb. Transcript levels of the gdhA gene were very high during the rapid growth phase and decreased drastically after 48 h of cultivation. Very high expression levels of the gdhA gene were observed in media with ammonium or asparagine as the nitrogen source, whereas glutamic acid repressed transcription of the gdhA gene. These results indicate that expression of the gdhA gene is subject to a strong nitrogen regulation at the transcriptional level.